EP3989686A1

EP3989686A1 - An electronic device configured to be mounted in a cluster housing and comprising a front tray for mounting at least one expansion card

Info

Publication number: EP3989686A1
Application number: EP20203326.2A
Authority: EP
Inventors: Sanjayakumar Halli; Prakash NAGARAJA; Sriprada Adiga; Kumar Avinash; Madhu Sharma; Pravin Kumar THAKUR
Original assignee: Atos Global IT Solutions and Services Pvt Ltd
Current assignee: Bull SA
Priority date: 2020-10-22
Filing date: 2020-10-22
Publication date: 2022-04-27
Also published as: US11672098B2; US20220132694A1

Abstract

An electronic device (D) configured to be mounted in a housing of a cluster, the device (D) comprising a rear body (2) housing at least one mother board (21) configured to be powered by the cluster, a front tray (3) housing at least one electronic board (31) having at least one socket (351), the front tray (3) comprising at least one fastening member (352) for mounting an expansion card (5) having an edge connector (52) and a fastening portion (53), the electronic board (31) being connected to the mother board (21) by at least one flexible cable (7), the front tray (3) being mounted slidable relatively from the rear body (2) between a close position and an open position in which the front tray (3) is at least partially removed from the cluster housing while keeping the rear body (2) into the cluster housing so that an expansion card (5) can be mounted/unmounted from the electronic board (31) without powering off the device (D).

Description

TECHNICAL FIELD

The present invention relates to a device in which an expansion card has to be mounted when the device is running.
As illustrated in Figure 1, a datacenter comprises several devices 200, such as servers, switches and routers, to organize, process and store data. A datacenter also comprises several racks, called "clusters C", arranged in rows within the datacenter and configured to house said devices 200. As represented in Figure 1, a cluster C comprises two vertical side walls delimiting a central cavity with a front opening, so as to define vertically stacked housings H. Each housing H is configured to house a device 200. Each device 200 comprises, within a main body 210, a mother board with several components (CPU, etc.) and optionally some expansion cards. Each device 200 is connected to a power distribution unit, known as PDU, and to a network thanks to a management node (not represented) located within the cluster C.
When the device 200 is running, the mother board and the expansion cards are electrically powered. If an expansion card is not working and needs to be replaced, the device 200 has to be switched off, removed from the cluster C, opened in order to access to the mother board. After replacement, the device 200 has to be put back in place. The maintenance of a device 200 is time consuming and requires to stop the services running on the device 200, which is a drawback.
Nowadays, expansion cards according to M.2 format are usually used. Such an expansion card is flat and has a rectangular shape. The expansion card comprises at least one processing module and one edge connector configured to be plugged into a socket on the mother board and one fastening portion configured to be secured to the mother board. In practice, a screw is used to secure the fastening portion to the mother board. When mounting such an expansion card, the edge connector is firstly inserted and then a screw is installed on the fastening portion to secure the expansion card. Such an expansion card requires some time for its installation and cannot be replaced directly by the customer.
The objective of the present invention is to provide a device configured to be mounted into a cluster housing in which expansion cards, such as M.2. expansion cards, can be easily replaced while the device is still running.

SUMMARY

The invention relates to an electronic device configured to be mounted in a housing of a cluster, the device comprising:

a rear body housing at least one mother board configured to be powered by the cluster,
a front tray housing at least one electronic board having at least one socket, the front tray comprising at least one fastening member for mounting an expansion card having an edge connector and a fastening portion,
the electronic board being connected to the mother board by at least one flexible cable, the front tray being mounted slidable relatively from the rear body between a close position and an open position in which the front tray is at least partially removed from the cluster housing while keeping the rear body into the cluster housing so that an expansion card can be mounted/unmounted from the electronic board without powering off the device.

Thanks to the invention, the front tray can be moved from a close position to an open position in which the socket and the fastening member are accessible for an operator. An expansion card can be removed easily without powering off the device.
Preferably, the fastening member comprises a latch for securing the mounting of the expansion card. Contrary to a screw which is an independent element, a latch is advantageously attached to the front tray and cannot be lost. The mounting/unmounting of an expansion card is easier and safer.
According to an aspect of the invention, the latch is slidable, preferably, horizontally. The latch can be manipulated by an operator with one hand which saves time and avoids any wrong manipulation.
Preferably, the latch comprises a spring configured to force the latch in a locking position. The locking is therefore automatic when the fastening portion of the expansion card is in the correct position. The operator doesn't need any tool such as a screwdriver.
According to another aspect of the invention, the front tray comprises at least one locking member configured to secure the front tray with the rear body of the device. The front tray cannot be opened by accident.
Preferably, the electronic device is a server.
Preferably, the at least one flexible cable transmits information and power so that the electronic board is still running in the open position.
Preferably, the front tray comprises sockets and fastening members for mounting at least four expansion cards, preferably, at least eight expansion cards.
According to an aspect of the invention, all the fastening members are located at the periphery of the front tray, preferably, along the lateral edges of the front tray. The fastening members are easily accessible for the operator when the front tray is open.
Preferably, the front tray comprises a horizontal panel for receiving the electronic board, a vertical front panel and two vertical lateral panels, each vertical lateral panel comprising at least one guiding member. The opening of the front tray is guided so that the flexible cable can be shortened or lengthened without damage. The guiding members increase the lifespan of the device. More preferably, the front tray comprises only four panels, the structure being simple.
The invention relates also to an assembly of an electronic device as presented before and at least one expansion card having:

an edge connector connected in the socket of the electronic board and
a fastening portion locked by the fastening member of the front tray.

Preferably, an expansion card is a M.2 expansion card. Such an expansion card, for example an SSD expansion card, can be immediately replaced without shutting down the device.
The invention relates also to a process for mounting an expansion card in the electronic device as presented before, the electronic device being mounted in a housing of a cluster and powered by the cluster, the front tray being in a close position, the process comprising the following steps:

Pulling the front tray relatively from the rear body in the open position in which the front tray is partially removed from the cluster housing while keeping the rear body into the cluster housing and
Mounting an expansion card on the electronic board without powering off the device.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be better understood by reading the description that follows, only given as an example, and by referring to the appended figures in which:

Figure 1 is a perspective view of a cluster with devices according to prior art;
Figure 2 is a perspective view of a cluster with devices according to the invention;
Figure 3 is a schematic view of an expansion card;
Figure 4 is a schematic view from the top of a device according to the invention in the close position;
Figure 5 is a schematic view from the top of a device according to the invention in the open position;
Figure 6 is a perspective view of a front tray from a device according to the invention;
Figure 7 is a perspective view of a latch from the front tray;
Figures 8 to 10 represent schematically the steps for unmounting an expansion card from a device according to the invention.

It should be noted that the figures set out the invention in a detailed manner to implement the invention, said figures obviously being able to serve to better define the invention if need be.

DETAILED DESCRIPTION

As illustrated in Figure 2, a datacenter comprises several devices D, such as servers, switches and routers, to organize, process and store data. A datacenter also comprises several racks, called "clusters C", arranged in rows within the datacenter and configured to house said devices D. As represented on Figure 2, a cluster C comprises two vertical side walls delimiting a central cavity with a front opening, so as to define vertically stacked housings H. Each housing H is configured to house a device D. Each device D is connected to a power distribution unit, known as PDU, and to a network thanks to a management node (not represented) located within the cluster C.
Each device D is defined in an orthogonal system (X, Y, Z) in which the X axis extends horizontally from the rear to the front, the Y axis extends laterally from the left to the right and the Z axis extends vertically from down to up.
A device D according to the invention is represented on Figures 4 and 5. In this example, the device D comprises a rear body 2 housing a mother board 21 configured to be powered by the cluster C and a front tray 3 housing an electronic board 31. In this example, the device D is a server but the invention applies to different devices (routers, switch, etc.).
The mother board 21 is a printed circuit board which is known from the person skilled in the art. The mother board 21 comprises for example a processor 210, a memory, etc. The mother board 21 comprises rear connectors 211 for power and communication which are connected to the cluster C.
The electronic board 31 is also a printed circuit board, preferably, a NVME back plane. In this example, the electronic board 31 is a slave board whereas the mother board 21 is a master board. As represented on Figures 4 and 5, the electronic board 31 comprises several sockets 351 for mounting expansion cards 5, in this example, eight expansion cards 5. It goes without saying that the number of expansion cards 5 could be different. The front tray 3 comprises several fastening members 352 for securing the expansion cards 5 when connected into the sockets 351. In this example, the fastening members 352 doesn't belong to the electronic board 31 but the opposite would be possible.
The mother board 21 is connected to the electronic board 31 by at least one flexible cable 7 in order to power the electronic board 31 and to allow transfer of information between the mother board 21 and the electronic board 31. Thanks to the flexibility and the length of the cable 7, the front tray 3 can be moved relatively from the rear body 2 without disconnecting the electronic board 31 from the mother board 21 as it will be explained later. In Figure 6, the electronic board 31 comprises a connector 71 for connecting the flexible cable 7.
In this example, each expansion card 5 has a M.2 format which is also known as NGFF (Next Generation Form Factor). The invention applies particularly for such M.2 format but also applies to other formats. The invention applies particularly for an SSD (Solid State Drive) expansion card 5.
As represented in Figure 3, each expansion card 5 is flat and has rectangular shape 50. Each expansion card 5 can have a different size. The expansion card 5 comprises at least one processing module 51, for example, a memory chip. Each expansion card 5 comprises one edge connector 52 configured to be plugged into a socket 351 on the electronic board 31 and one fastening portion 53 configured to be secured in order to avoid the removal of the edge connector 52 from the socket 351. The edge connector 52 comprises several pins. The fastening portion 53 is in the form of a recess having the shape of a half circle and is configured to receive a screw as presented in the preamble. The fastening portion 53 is located on the opposite edge of the edge connector 52.
As represented on Figure 6, the front tray 3 comprises a horizontal panel 301 for receiving the electronic board 31, a vertical front panel 302 and two vertical lateral panels 303.
As represented in Figure 5, the electronic board 31 has a width W31, defined along the Y axis, which is shorter than the width of the horizontal panel 301. The cost of the electronic board 31 is therefore reduced.
In this example, each vertical lateral panel 303 comprises one guiding member 33, for example, a roller or a slide. The guiding member 33 of the front tray 3 is configured to cooperate with the rear body 2, more particularly, with a guiding surface 23 of the rear body 2 (or a roller), so that the front tray 3 is mounted slidable relatively from the rear body 2 along the X axis in order for the front tray 3 to be at least partially removed from the cluster housing H while keeping the rear body 2 into the cluster housing H. Preferably, the front tray 3 is moved between a close position (use position), where the front tray 3 is in the cluster housing H, and an open position (maintenance position), where the front tray 3 is pulled toward the front. The distance L between the two positions is comprised between 10 cm and 14 cm. Such a distance L allows an operator to have sufficient room for mounting/unmounting expansion cards 5 as it will be presented later.
In this example, the vertical front panel 302 comprises connectors 34, located on the front face, connected to the electronic board 31 as represented on Figure 6. The front tray 3 comprises two locking members 32 configured to secure the front tray 3 with the rear body 2 in the close position. In this example, the front tray 3 comprises two screws which are located on the left and right portions of the vertical front panel 302. As represented in Figure 4, the locking members 32 cooperate with trough holes 22 of the rear body 2 so that the front tray 3 is not movable from the rear body 2 in the close position. Preferably, the locking members 32 are mounted captive with the vertical front panel 302.
In this example, the fastening members 352 doesn't belong to the electronic board 31 but belong to the horizontal panel 301 of the front tray 3. Thus, an expansion card 5 extends outside from the electronic board 3 when mounted as represented in Figure 5.
According to an aspect of the invention, each fastening member 352 of the electronic board 31 comprises a latch 8 for securing the mounting of the fastening portion 53 of the expansion card 5 as represented in Figures 6 and 7.
In this example, the latch 8 is slidable, preferably, horizontally along the Y axis as represented in Figure 7. Such a latch 8 is easy to manipulate by an operator since the vertical room is limited in a cluster environment. In this embodiment, as represented in Figure 7, the latch 8 comprises a main body 81 which is slidable on a rail 82 secured to the horizontal panel 301 between a free position and a locking position. Preferably, the latch 8 comprises a spring 83, mounted between the main body 81 and the rail 82, which is configured to force the latch 8 in the locking position. In other words, thanks to the spring 83, the locking is automatic. More preferably, the spring 83 forces the main body 81 into the recess of the fastening portion 53 of the expansion card 5. In order to secure the expansion card 5 efficiently, the main body 81 has a shape which cooperates with the recess curvature of the fastening portion 53 of the expansion card 5.
In order to facilitate the mounting/unmounting of the expansion cards 5, all the fastening members 352 are located at the periphery of the front tray 3, preferably along the lateral edges of the horizontal panel 301 of the front tray 3. Preferably, all the sockets 351 are located at the periphery of the electronic board 31. Such an arrangement is advantageous since it is easier for an operator to access the fastening members 352 and manipulate the latches 8 from the lateral edges of the tray 3 in the open position. The mounting/unmounting is easy and fast.
A process for mounting an expansion card 5 in the electronic device D will be now described in reference to Figures 8 to 10.
In this example, the electronic device D is mounted in a housing H of a cluster C and powered by the cluster C. The front tray 3 is in a close position (use position).
An operator unlocks the front tray 3 by unscrewing the locking members 32 from the vertical front panel 302 as represented in Figure 8. The front tray 3 is no more secured to the rear body 2.
An operator pulls the front tray 3 relatively from the rear body 2 in order for the front tray 3 to be at least partially removed from the cluster housing H while keeping the rear body 2 into the cluster housing H as represented in Figure 9. The front tray 3 slides along the X axis relatively to the rear body 2 thanks to the guiding members 33 in the open position (maintenance position). The front tray 3 extends outside from the cluster housing H along a distance L comprises between 10 cm to 14 cm. It allows on operator to access the electronic board 31 of the front tray 3. Advantageously, the electronic board 31 is still connected to the mother board 21 thanks to the cable 7 which maintains a connection in the close position and in the open position. The device D is still functioning which is very advantageous.
Since the latches 8 are located at the periphery of the front tray 3, and more specifically along the left and right edges of the horizontal panel 301, they are easily accessible for an operator when the front tray 3 is in the open position.
The operator can slide the latch 8 securing the expansion card 5 which needs to be replaced in order to free the fastening portion 53 of the expansion card 5 as represented in Figure 10. The operation is easy and can be performed with one finger. Due to the connection with the edge connector 52, the expansion card 5 tilts and allows the operator to simply remove the expansion card 5 from the socket 351 of the electronic board 31 as represented in Figure 10.
Similarly, a new expansion card 5 can be mounted at the same position by inserting the edge connector 52 in the socket 351 and by securing the fastening portion 53 to the horizontal panel 301. The operator manipulates the latch 8 to the free position (against the spring force) to let the fastening portion 53 move towards the horizontal panel 301 and then let the latch 8 moves back to the locking position to secure the expansion card 5 on the horizontal panel 301. The front tray 3 can be put back to the close position and locked.
Thanks to the invention, an expansion card 5 can be replaced by an operator with no waste of time. Advantageously, the replacement can be performed without shutting down the device D which can still run services.

Claims

An electronic device (D) configured to be mounted in a housing (H) of a cluster (C), the device (D) comprising:
- a rear body (2) housing at least one mother board (21) configured to be powered by the cluster (C),

- a front tray (3) housing at least one electronic board (31) having at least one socket (351), the front tray (3) comprising at least one fastening member (352) for mounting an expansion card (5) having an edge connector (52) and a fastening portion (53),

- the electronic board (31) being connected to the mother board (21) by at least one flexible cable (7), the front tray (3) being mounted slidable relatively from the rear body (2) between a close position and an open position in which the front tray (3) is at least partially removed from the cluster housing (H) while keeping the rear body (2) into the cluster housing (H) so that an expansion card (5) can be mounted/unmounted from the electronic board (31) without powering off the device (D).
An electronic device (D) according to claim 1, wherein the fastening member (352) comprises a latch (8) for securing the mounting of the expansion card (5).
An electronic device (D) according to one of the claims 1 to 2, wherein the latch (8) is slidable, preferably, horizontally.
An electronic device (D) according to one of the claims 1 to 3, wherein the latch (8) comprises a spring (83) configured to force the latch (8) in a locking position.
An electronic device (D) according to one of the claims 1 to 4, wherein the front tray (3) comprises at least one locking member (32) configured to secure the front tray (3) with the rear body (2) of the device (D).
An electronic device (D) according to one of the claims 1 to 5, wherein the electronic device (D) is a server.
An electronic device (D) according to one of the claims 1 to 6, wherein the at least one flexible cable (7) transmits information and power.
An electronic device (D) according to one of the claims 1 to 7, wherein the front tray (3) comprises sockets (351) and fastening members (352) for mounting at least four expansion cards (5), preferably, at least eight expansion cards (5).
An electronic device (D) according to claim 8, wherein all the fastening members (352) are located at the periphery of the front tray (3), preferably, along the lateral edges of the front tray (3).
An electronic device (D) according to one of the claims 1 to 9, wherein the front tray (3) comprises a horizontal panel (301) for receiving the electronic board (31), a vertical front panel (302) and two vertical lateral panels (303), each vertical lateral panel (303) comprising at least one guiding member (33).
An assembly of an electronic device (D) according to one of the claims 1 to 10 and at least one expansion card (5) having:
- an edge connector (52) connected in the socket (351) of the electronic board (31) and

- a fastening portion (53) locked by the fastening member (352) of the front tray (3).
An assembly according to claim 11 in which the expansion card (5) is a M.2 expansion card.
A process for mounting an expansion card (5) in the electronic device (D) according to one of the claims 1 to 10, the electronic device (D) being mounted in a housing (H) of a cluster (C) and powered by the cluster (C), the front tray (3) being in a close position, the process comprising the following steps:
- Pulling the front tray (3) relatively from the rear body (2) in the open position in which the front tray (3) is partially removed from the cluster housing (H) while keeping the rear body (2) into the cluster housing (H) and

- Mounting an expansion card (5) on the electronic board (31) without powering off the device (D).